Simultaneous detection of centromere-specific probes and chromosome painting libraries by a combination of primedin situ labelling and chromosome painting (PRINS-painting)

In situ techniques for the detection of specific chromosomes using centromeric probes and the decoration of entire chromosomes using chromosome painting are well established. However, in the deciphering of complex chromosomal aberrations it is valuable to be able to detect the centromere and the entire DNA of a specific chromosome in different colours simultaneously on the same metaphase. In this report we describe a combination of the primedin situ labelling (PRINS) technique and chromosome painting for simultaneous visualization of centromere-specific oligonucleotides and chromosome painting libraries. A key feature is that the denaturation step in the PRINS reaction is sufficient to keep the chromosomes denatured for chromosome painting. This means that PRINS and consecutive chromosome painting can be performed as a single procedure (PRINS-painting)     

Localization of the human membrane-type 2 matrix metalloproteinase gene (MMP15) to 16q12.1 near DNA elements that are part of centromeric and non-centromeric heterochromatin of 11 human chromosomes

We have localized a second gene for membrane-type matrix metalloproteinases, MT2-MMP, to chromosome 16q12 by in situ hybridization. FISH experiments using a genomic PAC clone containing the MT2-MMP gene resulted in an unusual hybridization pattern detecting centromeric and non-centromeric heterochromatin regions or its flanking sequences in 11 human chromosomes in addition to the MT2-MMP locus on chromosome 16q12. The detailed analysis of this hybridization pattern using molecular cytogenetic methods together with the specific hybridization of the MT2-MMP cDNA allowed a refined mapping of the gene to 16q12.1, directly adjacent to the 16q heterochromatin. Our findings may give some insights into the evolution of the MMP gene family.     

Direction of DNA sequences within chromatids determined using strand-specific FISH

The 5 to 3 direction of DNA strands within chromatids of metaphase chromosomes can be determined by using simultaneous hybridization of a single strand of the telomere probe and a single strand of a repetitive sequence to slides pretreated for strand-specific hybridization. The telomere probe identifies the direction of the DNA helical strand remaining in each chromatid of the metaphase chromosomes. The direction of the repetitive sequence is then determined from the direction of the strand to which it hybridizes. This method was used to determine the 5 to 3 direction of three repetitive DNA sequences, each for a different human repeat family.     

Polymerase chain reaction-based suppression of repetitive sequences in whole chromosome painting probes for FISH

We have developed a method to suppress the PCR amplification of repetitive sequences in whole chromosome painting probes by adding Cot-1 DNA to the amplification mixture. The repetitive sequences in the Cot-1 DNA bind to their homologous sequences in the probe library, prevent the binding of primers, and interfere with extension of the probe sequences, greatly decreasing PCR efficiency selectively across these blocked regions. A second labelling reaction is then done and this product is resuspended in FISH hybridization mixture without further addition of blocking DNA. The hybridization produces little if any non-specific binding on any other chromosomes. We have been able to successfully use this procedure with both human and rat chromosome probes. This technique should be applicable in producing probes for CGH, M-FISH and SKY, as well as reducing the presence of repetitive DNA in genomic libraries     

Detection of Y chromosome sequences in a 45,X/46,XXq– patient by Southern blot analysis of PCR-amplified DNA and fluorescent in situ hybridization (FISH)

In some cases of gonadal dysgenesis, cytogenetic analysis seems to be discordant with the phenotype of the patients. We have applied techniques such as Southern blot analysis and fluorescent in situ hybridization (FISH) to resolve the phenotype/genotype discrepancy in a patient with ambiguous genitalia in whom the peripheral blood karyotype was 45,X. Gonadectomy at age 7 months showed the gonadal tissue to be prepubertal testis on the left side and a streak gonad on the right. The karyotype obtained from the left gonad was 45,X/46,XXq- and that from the right gonad was 45,X. Three different techniques, PCR amplification, FISH, and chromosome painting for X and Y chromosomes, confirmed the presence of Y chromosome sequences. Five different tissues were evaluated. The highest percentage of Y chromosome positive cells were detected in the left gonad, followed by the peripheral blood lymphocytes, skin fibroblasts, and buccal mucosa. No Y chromosomal material could be identified in the right gonad. Since the Xq- chromosome is present in the left gonad (testis), it is likely that the Xq- contains Y chromosomal material. Sophisticated analysis in this patient showed that she has at least 2 cell lines, one of which contains Y chromosomal material. © 1995 Wiley-Liss, Inc.     

一种能精确检测人间期细胞核中21号染色体拷贝数的DNA探针

目的制备能精确检测人类间期细胞核中２１号染色体拷贝数的ＦＩＳＨ探针。方法利用万能引物ＰＣＲ法,从定位于人２１ｑ１１的ＹＡＣ克隆８８１Ｄ２分离制备ＤＮＡ探针,并用于与８例正常人和５例２１三体患者的外周血淋巴细胞中期相和间期核,及经细胞松弛素Ｂ（ｃｙｔｏｃｈａｌａｓｉｎＢ）诱导的双核细胞进行ＦＩＳＨ分析。结果该探针具有以下特点：（１）长度集中于３５０～７５０ｂｐ;（２）其靶序列位于２１号染色体长臂上且紧靠着丝粒;（３）特异性强;（４）杂交信号明亮,容易辨认;（５）对中期相及间期细胞核中２１号染色体的检出率分别高达９９．６０％和９８．４０％。结论制备的ＤＮＡ探针能精确检测人类间期细胞核中２１号染色体的拷贝数,且适用于细胞分裂时２１号染色体分离情况的研究     

Multipaint FISH: a rapid and reliable way to define cryptic and complex abnormalities

We present the use of a multipaint fluorescence in situ hybridisation (FISH) approach for the detection and interpretation of chromosome abnormalities that could not be resolved by conventional cytogenetics alone. In case 1, a de novo add(Xp) was shown to be an unbalanced X;12 translocation; in case 2, a complex rearrangement involving a deletion of 5p was shown to include a previously undetected cryptic 5;6 translocation. In addition, in case 3, this technique defined additional complexities and nine breakpoints in an acquired rearrangement of chromosomes 2, 9, 11, 16 and 22 in a patient with myelodysplasia. The technique allows the simultaneous identification of up to 24 chromosomes on a single slide using FISH with directly labelled whole chromosome paints. This simple and rapid method does not require image enhancement, produces results within 48 h and, therefore, offers an alternative to other recent developments, such as combinatorial multifluor FISH, spectral karyotyping or comparative genomic hybridisation.     

Possible origin of a B chromosome deduced from its DNA composition using double FISH technique

Double fluorescentin situ hybridization (FISH) with two DNA probes (a 180 bp tandemly repeated DNA and ribosomal DNA) was performed in embryo cells of the grasshopperEyprepocnemis plorans. Repetitive DNA was present in most standard chromosomes (excepting 7, 8 and 10) and in the proximal two-thirds of the B chromosome, which was its major location in the complement. Ribosomal DNA was present distally on the B, and in the active nucleolar organizer regions (NORs) of the X, 9, 10 and 11 chromosomes. A small number of rRNA gene clusters was also observed in the pericentromeric regions of chromosomes 1–8. The double FISH technique showed that the B chromosome (B₂ type) is mainly composed of a 180 bp tandem repeat and ribosomal DNA, the minute short arm being the only region that does not hybridize with them. The location and order of the centromere and both the DNA sequences on the B chromosome coincide only with those in the X chromosome, indicating that the B most probably derives from the X.     

FISH mapping and molecular organization of the major repetitive sequences of tomato

This paper presents a bird’s-eye view of the major repeats and chromatin types of tomato. Using fluorescence in-situ hybridization (FISH) with Cot-1, Cot-10 and Cot-100 DNA as probes we mapped repetitive sequences of different complexity on pachytene complements. Cot-100 was found to cover all heterochromatin regions, and could be used to identify repeat-rich clones in BAC filter hybridization. Next we established the chromosomal locations of the tandem and dispersed repeats with respect to euchromatin, nucleolar organizer regions (NORs), heterochromatin, and centromeres. The tomato genomic repeats TGRII and TGRIII appeared to be major components of the pericentromeres, whereas the newly discovered TGRIV repeat was found mainly in the structural centromeres. The highly methylated NOR of chromosome 2 is rich in [GACA]₄, a microsatellite that also forms part of the pericentromeres, together with [GA]₈, [GATA]₄ and Ty1-copia. Based on the morphology of pachytene chromosomes and the distribution of repeats studied so far, we now propose six different chromatin classes for tomato: (1) euchromatin, (2) chromomeres, (3) distal heterochromatin and interstitial heterochromatic knobs, (4) pericentromere heterochromatin, (5) functional centromere heterochromatin and (6) nucleolar organizer region.     

Isolation and characterization of a DNA fragment containing various kinds of repetitive sequences located on human chromosome 21

Summary In order to investigate the repetitive sequences located on human chromosome 21, we have isolated DNA fragments containing Alu sequences. One of the clones, p1, was chosen for further study, because it contained repetitive sequences different from the Alu sequence. Nucleotide sequence analysis of p1 indicates that p1 contains L1 and O-family sequences. Interestingly, when the L1 sequence was used as a probe, a discrete band of 5 kb was seen in HindIII-digested DNA from somatic cell hydbrids containing human chromosome 21 as the sole human chromosome. The L1 sequence was rearranged and was interrupted by O-family sequence, which wasd flanked by 6 bp target site dup litations. Since all three repetitive sequences are known to act as retroposons, these results imply that there is an integration hot spot on human chromosome 21. The sequence was mapped within 21q11–21.     

Mapping and organization of highly-repeated DNA sequences by means of simultaneous and sequential FISH and C-banding in 6×-triticale

Three families of highly repeated sequences from rye and the rRNA multigenes (NOR and 5S) have been mapped by FISH and C-banding, in chromosomes of triticale. The pSc119.2 probe showed interstitial hybridization in chromosome arms 1RS, 1RL, 4RL, 5RL, 6RS, 6RL, 7RS and 7RL, and is very effective for chromosome identification of rye chromosomes in triticale. This sequence also hybridizes to the 4A, 5A and the seven B-genome wheat chromosomes. Simultaneous hybridization with the pSc119.2 and pTa794 (5S rRNA) is very useful to distinguish the metacentric chromosomes 2R and 3R. The pSc74 probe appears at interstitial sites in the long arm of the most heterobrachial chromosomes (5R and 6R). The three repetitive sequences of 120 bp, 480 bp, and 610 bp hybridize to telomeric regions in rye chromosomes. Different arrangements and complex organizations consisting of arrays of three or more family sequences were found. The results demonstrate a great variation in the relative arrangement of the repetitive sequences in the telomeres of the rye chromosomes. There were quantitative differences in each cytological marker between triticale lines in bothin situ labelling and C-banding, probably as the result of differences in the number and/or kind of repeat sequence.     

高分辨率熔解曲线小扩增子法结合混样法在线粒体13928G〉C突变分析中的应用

目的探讨高分辨率熔解曲线（high resolution melting,HRM）技术在线粒体13928G〉C突变分析中应用的可行性。方法在PCR前,体系中加入饱和染料、高温寡核苷酸内参（96℃）、低温寡核苷酸内参（60℃）和与待测样本等体积的已知基因型为GG的模板进行混样扩增,运用HRM技术对定量DNA的PCR产物进行基因分型,并从中随机抽取20例进行测序验证。结果930例样本中野生型GG占728例,突变型CC占202例;DNA定量有助于HRM分析时对分型结果的判断;同时联合运用高、低温内参比只用一种内参分型效果好;随机抽取的20例样本的测序结果与HRM分型结果相一致。结论运用高分辨率熔解曲线小扩增子法结合混样法可对线粒体基因组13928G〉C突变进行准确分型。     

Satellite III sequences on 14p and their relevance to Robertsonian translocation formation

Robertsonian translocations (ROBs) are the most common rearrangements in humans, contributing significantly to genetic imbalance, fetal wastage, mental retardation and birth defects. Rob(14q21q) and rob(13q14q), which are formed predominantly during female meiosis, comprise the majority (85%) of all ROBs. Previous studies have shown that the breakpoints are consistently located within specific regions of the proximal short arms of chromosomes 13, 14, and 21. The high prevalence of these translocations, the consistent breakpoints found, and the fact that roughly 50% of cases occur sporadically suggest that the sequences at or near the breakpoints confer susceptibility to chromosome rearrangement and that the rearrangements occur through a specific mechanism. To investigate this hypothesis, we developed hamster–human somatic cell hybrids derived from de novo rob(14q21q) patients that contained the translocated chromosome segregated from the other acrocentric chromosomes. We determined the physical order of five satellite III subfamilies on 14p, and investigated their involvement in formation of these de novo translocations.     

Genomic Differentiation of 18S Ribosomal DNA and β-Satellite DNA in the Hominoid and its Evolutionary Aspects

The chromosome localization of two human multisequence families, rDNA and β-satellite (β-sat) DNA, was determined in humans and apes using double color fluorescence in-situ hybridization. Both DNA probes showed a distinct hybridization pattern with species-specific variations in hominoids. The stepwise differentiation of the integration, amplification, multilocalization, and reduction of the DNAs were observed interspecifically through the seven species examined. The stepwise events allowed us to trace back a phylogenetic divergence of the hominoid at the cytogenetic level. The manifestation of the events revealed that variations of the Y chromosome and acrocentric autosomes were synapomorphic characters in the divergence and those of metacentric autosomes were autapomorphic characters. Multilocalization of rDNA in the hominoid could also be interpreted as a result of translocations in terms of hetero-site crossover followed by a centric fission and formation of an acrocentric chromosome. Based on the observed rearrangements of rDNA and β-sat DNA, we propose the following chromosomal phylogenetic divergence order in hominoids: gibbon-siamang-orangutan-gorilla-human-chimpanzee-bonobo. Our data provide additional evidence that evolution of the hominoid can be effectively studied using cytogenetic approaches. This revised version was published online in August 2006 with corrections to the Cover Date.     

Isolation, characterization and chromosome localization of repetitive DNA sequences in bananas (Musa spp.)

Partial genomic DNA libraries were constructed in Musa acuminata and M. balbisiana and screened for clones carrying repeated sequences, and sequences carrying rDNA. Isolated clones were characterized in terms of copy number, genomic distribution in M. acuminata and M. balbisiana, and sequence similarity to known DNA sequences. Ribosomal RNA genes have been the most abundant sequences recovered. FISH with probes for DNA clones Radka1 and Radka7, which carry different fragments of Musa 26S rDNA, and Radka14, for which no homology with known DNA sequences has been found, resulted in clear signals at secondary constrictions. Only one clone carrying 5S rDNA, named Radka2, has been recovered. All remaining DNA clones exhibited more or less pronounced clustering at centromeric regions. The study revealed small differences in genomic distribution of repetitive DNA sequences between M. acuminata and M. balbisiana, the only exception being the 5S rDNA where the two Musa clones under study differed in the number of sites. All repetitive sequences were more abundant in M. acuminata whose genome is about 12% larger than that of M. balbisiana. While, for some sequences, the differences in copy number between the species were relatively small, for some of them, e.g. Radka5, the difference was almost thirty-fold. These observations suggest that repetitive DNA sequences contribute to the difference in genome size between both species, albeit to different extents. Isolation and characterization of new repetitive DNA sequences improves the knowledge of long-range organization of chromosomes in Musa. This revised version was published online in July 2006 with corrections to the Cover Date.     

Characterization of Reciprocal Translocations in Pigs using Dual-colour Chromosome Painting and Primed in situ DNA Labelling

We report the use of dual-colour chromosome painting to determine the exact nature of certain chromosome rearrangements observed in the pig (Sus scrofa domestica). The chromosomal abnormalities were detected by GTG- and RBG-banding techniques. The initially proposed interpretations were: (1) rcp(6;13)(p1.5;q4.1); (2) rcp(11;16)(p1.4;q1.4); (3) rcp(6;16)(p1.1;q1.1); (4) rcp(13;17)(q4.1;q1.1); (5) rcp(6;14)(q2.7;q2.1); (6) rcp(3;5)(p1.3;q2.3); (7) rcp(2; 14)(q1.3;q2.7); (8) rcp(15;17)(q1.3;q2.1). Hybridizations were carried out with biotin- and digoxigenin-labelled probes obtained by priming authorizing random mismatches polymerase chain reaction (PARM-PCR) amplification of porcine flow-sorted chromosomes. In some cases, i.e. (1), (4), (5), (6), (7) and (8), the fluorescence in situ hybridization (FISH) results allowed confirmation of the interpretations proposed with classical cytogenetic methods. Chromosome painting proved the reciprocity of the translocation in cases (1), (6) and (8), whereas modifications of the formula were proposed for case (2). Primed in situ DNA labelling (PRINS) experiments have also been carried out in case (3) using a primer specific for the centromeres of acrocentric chromosomes (first experiment) or a primer specific for the centromeres of a subset of meta- and submetacentric chromosomes including chromosome 6 (second experiment). It allowed us to demonstrate that the breakpoints occurred in the centromeric region of chromosome 16 and in the p arm of chromosome 6, just above the centromere.     

The chromosome complement of Olea europaea L.: characterization by differential staining of the chromatin and in-situ hybridization of highly repeated DNA sequences

The chromosome complement of olive (Olea europaea L.) has been characterized by differential staining of the chromatin and chromosomal localization of highly repeated DNA sequences and ribosomal cistrons. DAPI staining produces different-sized positive bands in various locations on all the chromosomes. By combining this band pattern with the results obtained from cytological hybridization of OeTaq80, OeTaq178, and OeGEM86 DNA tandem repeats, most of the pairs can be distinguished from each other, in spite of the large number of chromosomes (2n=46), their small size and similar morphology. Different tandem-repeated DNA sequences may be contained into single heterochromatic chromosome regions, even though there are regions where repeats of only one family are present. OeTaq80- and OeGEM86-related DNA sequences are rather specific to the heterochromatin at the chromosome ends, while most sequences related to the longer OeTaq178 probe are confined to interstitial heterochromatin. Some exceptions suggest that major chromosomal rearrangements occurred during genome evolution. Polymorphism, which may differentiate olive cultivars, was observed within chromosome pairs I, V, and VII.